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2025 Operational Overview of the Photovoltaic Patterned Glass Industry Against the backdrop of the accelerated global energy transition, China's photovoltaic patterned glass industry, as a critical link in the photovoltaic industry chain in 2025, exhibited distinct characteristics of "orderly capacity expansion, rapid technological iteration, and continuous structural optimization," moving towards a new stage of high-quality development.   I. Industry Operational Data: Synergistic Growth in Output and Efficiency, Continuous Optimization of Supply-Demand Structure From January to November 2025, the cumulative national output of photovoltaic patterned glass reached 23.5 million tons, a year-on-year increase of 18.7%, demonstrating robust supply capabilities. The industry achieved a total operating revenue of 185 billion yuan and a total profit of 21 billion yuan, representing year-on-year growth of 15.2% and 12.8%, respectively, with the industry maintaining a healthy overall profitability level. Regarding the supply-demand relationship, downstream demand for photovoltaic installations remained strong. In the first three quarters of 2025, newly added national photovoltaic installed capacity exceeded 120 GW, a year-on-year increase of 25%, directly driving stable demand for photovoltaic glass. The overall industry capacity utilization rate remained within a reasonable range around 85%. The market shifted from past "aggregate oversupply" to the current "structural tight balance." Specifically, this manifests as: tight supply of high-transmittance, ultra-thin glass compatible with high-efficiency cell technologies like N-type TOPCon and HJT, while supply of standard specification products remained ample.   II. Capacity and Layout: Deepening of Clustered Development, New Capacity Expansion Becomes More Rational (1) Highly Concentrated Capacity Distribution, Industrial Base Advantages Strengthened China's photovoltaic patterned glass production capacity continues to concentrate in regions with resource and energy advantages. The combined capacity of the five major industrial bases—Fengyang in Anhui, Beihai in Guangxi, Xuzhou in Jiangsu, Shahe in Hebei, and Qujing in Yunnan—now accounts for over 70% of the national total capacity. Among them, Fengyang, Anhui, leveraging its unique high-quality quartz sand resources and a complete industry chain ecosystem, has developed into the world's largest photovoltaic glass production base. (2) Steady Pace of Capacity Expansion, Clear Structural Optimization Features Compared with the aggressive expansion in earlier years, industry capacity growth in 2025 became more rational and optimized. Twelve new photovoltaic patterned glass production lines were added throughout the year, adding a daily melting capacity of 9,500 tons, with the growth rate decelerating year-on-year. Crucially, nearly all new capacity was for high-quality ultra-clear patterned glass production lines, while traditional ordinary patterned glass capacity accelerated its phase-out, indicating a pronounced trend of high-end substitution.   III. Technological Innovation and Product Evolution: Thinner, Higher Transmittance, and Functionalization Become Core Directions (1) Continuous Breakthroughs in Transmittance and Efficiency Enhancement Improving glass transmittance is a direct path to increasing module power generation efficiency. In 2025, the mainstream industry product transmittance generally reached 94.2% or higher. Leading enterprises, through optimizing patterning processes and anti-reflective coating technology, have pushed transmittance beyond 94.5%, delivering significant power gains for photovoltaic modules. (2) Accelerated Thinning Process, Significant Cost Reduction Effects Reducing glass thickness is an important cost-reduction path for the industry. In 2025, the market share of glass with a thickness of 2.0mm and below increased to 65%. Ultra-thin 1.6mm photovoltaic glass also began mass production and application. Compared to traditional 3.2mm glass, using ultra-thin glass can reduce module weight by over 40% and significantly decrease glass substrate usage, offering substantial economic benefits.   (3) Functional Products Expand Application Scenarios To meet diversified market demands, various types of functional photovoltaic glass rapidly emerged. Beyond mainstream high-transmittance glass, differentiated products like colored glass, anti-dust glass, and self-cleaning glass, suitable for distributed PV and BIPV (Building-Integrated Photovoltaics), saw their market share steadily increase. Meanwhile, the share of double-glass modules remained stable around 45%, driving synchronous growth in demand for backsheet glass. IV. Cost and Competitive Landscape: Strengthened Cost Control, Increased Market Concentration (1) Balancing Raw Material and Energy Costs Amidst Fluctuations In 2025, the price of the main raw material soda ash decreased year-on-year, alleviating some cost pressure. However, high-quality low-iron quartz sand remained price-resilient due to resource scarcity. Regarding energy costs, the industry continued to reduce average natural gas consumption and overall energy intensity by promoting technologies like larger furnaces, full-oxygen combustion, and waste heat recovery, effectively countering energy price fluctuations. (2) Further Increase in Market Concentration, Differentiation in Competition Tiers The industry's CR5 (concentration ratio of the top five enterprises) reached 68% in 2025, with leading firms consolidating their advantages in technology, scale, customer base, and supply chain. Concurrently, market competition exhibited hierarchical differentiation: leading enterprises engage in scale-based competition relying on large furnaces and global presence; numerous small and medium-sized enterprises focus on niche markets like specialty glass and BIPV customization, pursuing a differentiated development path of "specialization, refinement, uniqueness, and innovation." (3) Solid International Competitiveness, Sustained Export Growth China's position in the global photovoltaic patterned glass supply chain remains formidable. Product exports reached 4.8 million tons in 2025, a year-on-year increase of 22%, accounting for approximately 78% of the global market share. In key overseas markets like Southeast Asia and Europe, Chinese products maintained very high market shares due to their exceptional cost-performance ratio and stable supply capabilities.   V. Policy and Future Outlook: Green Regulations Lead the Way, Clear Path for High-Quality Development (1) Industrial Policies Guide Standardized Development In 2025, the Ministry of Industry and Information Technology optimized capacity replacement policies, offering support for photovoltaic patterned glass projects with advanced energy efficiency and environmental performance. This aims to encourage high-quality capacity and phase out outdated capacity. Simultaneously, as more enterprises are incorporated into the national carbon market, the industry faces increased pressure and motivation for carbon emission reduction, driving the green and low-carbon transition.   (2) Challenges and Future Trends The industry still faces challenges such as securing high-quality quartz sand resources and navigating international trade barriers. Looking ahead, clear industry trends include: Technological Advancement: Continued evolution towards thinner, more transparent, stronger, and lower-carbon glass. Greener Production: Deep decarbonization technologies like hydrogen firing and direct green power supply will move from demonstration to application. Scenario-Specific Products: Developing specialized products for unique environments like deserts, coastal areas, and extreme cold, and deepening integration with sectors like construction and transportation. In summary, in 2025, China's photovoltaic patterned glass industry focused not only on steady scale growth but also on enhancing intrinsic quality and optimizing structure. Through continuous technological iteration, cost control, and green transition, the industry is consolidating its global leading advantage, providing a solid and reliable foundation of critical materials to support the ongoing cost reduction and efficiency improvement of the photovoltaic industry and to help achieve global energy transition goals.

Key Process Points for Heating Temperature Control in Glass Tempering Process In the glass tempering production process, the reasonable selection of heating temperature and effective control of furnace temperature are core links determining product quality, directly affecting the tempering strength, flatness and yield rate of glass. The formation principle of temperedglass is to heat the glass to a softened state at high temperature, then form surface compressive stress and internal tensile stress through rapid and uniform cooling, thereby significantly improving the mechanical properties and safety performance of glass. The foundation of this series of physical changes lies in precise temperature control and scientific process parameter setting. This article will elaborate on key points such as heating temperature selection, furnace temperature control, heating time setting, glass arrangement specifications, cooling process requirements and glass movement control in combination with production practice.   I. Core Logic of Reasonable Selection of Heating Temperature and Effective Control of Furnace Temperature In glass tempering production, the load condition of the electric furnace is the core basis for determining the heating temperature. However, it should be clarified that the electric furnace load mentioned here does not refer to the plane area occupied by glass in the electric furnace, but specifically refers to the dynamic balance relationship betweenglass thickness, heating temperature and heating time. This relationship runs through the entire tempering heating process and is the fundamental principle for formulating heating process parameters. Different thicknesses of glass have significant differences in heat demand: thin glass has a fast heating rate and small heat capacity, while thick glass is the opposite. Ignoring this difference and setting the temperature blindly can easily lead to problems such as uneven heating, overheating or underheating of glass. From the perspective of mainstream production equipment in the industry, the heating section of tempered electric furnaces used by most manufacturers adopts a zoned heating design, which can be divided into multiple independent small heating zones. The core advantage of this design is that it can realize targeted temperature regulation and ensure the uniformity of the temperature field in the furnace. Under normal production conditions, there is always glass in the heating area of the heating element at the midpoint of the electric furnace that is absorbing heat, and the continuous transportation of glass is maintained in the entire working area of the electric furnace, forming a regional balance between heating and heat absorption. This regional balance directly determines the local heating effect. When the heat consumption rate in a certain area exceeds the heat supply rate of the heating element, the temperature in that area will drop significantly, which is the formation of overload phenomenon.   It should be emphasized that the success of glass tempering depends on the heating quality of the low-temperature area of the glass sheet. As a poor conductor of heat, if local temperature drop occurs in the furnace, it will lead to excessive temperature difference in various parts of the glass sheet. In the subsequent cooling stage, the shrinkage rate of different areas is inconsistent, generating huge internal stress. When this internal stress exceeds the bearing capacity of the glass itself, it will cause glass breakage and production loss. Therefore, effectively avoiding the overload phenomenon and maintaining the stable temperature of each area in the furnace are the core objectives of heating temperature control.   To realize the effective control of furnace temperature, in addition to accurately setting the heating temperature according to the load condition, it is also necessary to equip a complete temperature monitoring and feedback regulation system. By arranging temperature sensors in different areas of the furnace, real-time temperature data can be collected and transmitted to the control system. When it is detected that the temperature in a certain area deviates from the set value, the system can automatically adjust the power of the heating element in that area to make up for the heat loss in time. At the same time, operators need to regularly inspect and calibrate the heating elements and temperature sensors to ensure that the equipment is in good working condition and avoid temperature control failure caused by equipment faults. In addition, the sealing performance of the furnace body also affects temperature stability. Problems such as poor sealing of the furnace door and damage to the thermal insulation layer of the furnace body will cause heat loss and destroy the balance of the temperature field in the furnace. Therefore, daily maintenance of the furnace body should be strengthened to ensure the sealing and thermal insulation effect.   II. Scientific Setting of Heating Time to Ensure Sufficiency and Uniformity of Heating On the basis of determining the heating temperature, the reasonable setting of heating time is also crucial. The heating power of the tempering furnace is basically fixed when the equipment leaves the factory, so the heating time becomes a key parameter for adjusting the heat absorption of glass. If the heating time is too short, the glass cannot reach a fully softened state, and a uniform stress layer cannot be formed after cooling, resulting in insufficient tempering strength. If the heating time is too long, the glass is prone to over-softening, leading to surface deformation, edge bending, and even defects such as bubbles and stones, which also affect product quality. Combined with industry production experience, the setting of heating time usually takes glass thickness as the core basis, forming a relatively mature reference standard: for glass of conventional thickness, the heating time is about 35~40 seconds per millimeter of thickness. For example, when producing tempered glass with a thickness of 6mm, the heating time can be set according to the standard of 6×38 seconds = 228 seconds (38 seconds is the intermediate reference value in the range of 35~40 seconds, and can be fine-tuned according to factors such as glass type and ambient temperature in actual production). For thickglass with a larger thickness of 12~19mm, due to its lower heat conduction efficiency, a longer heating time is required to ensure sufficient internal heating. Therefore, the basic calculation method of heating time is adjusted to 40~45 seconds per 1mm thickness.   It should be noted that the above heating time standard is only a basic reference, and flexible adjustment should be made by comprehensively considering various factors in actual production. For example, different types ofglass have differences in physical properties such as specific heat capacity and softening temperature, so the heating time of ordinary float glass and Low-E coated glass needs to be different. Changes in ambient temperature will also affect heating efficiency. In low-temperature environments in winter, the initial temperature of glass is low, and the heating time needs to be appropriately extended. In addition, the placement density of glass in the electric furnace and the air flow state in the furnace will also affect the heating time. Therefore, operators need to continuously accumulate experience in the production process and dynamically optimize the heating time according to the actual production situation to ensure the sufficiency and uniformity of glass heating.   III. Optimizing Glass Placement Arrangement to Ensure Uniformity of Furnace Load To realize the uniform heating of glass, in addition to precise control of temperature and time, the arrangement method of glass on the sheet feeding table also plays an important role. The core goal of reasonable placement arrangement is to ensure the uniformity of vertical and horizontal loads in the electric furnace, avoid local glass being too dense or too sparse, thereby maintaining the stability of the temperature field in the furnace and improving the overall heating effect. Specifically, the standard requirements for placement arrangement mainly include the following two aspects: Uniform placement layout of glass in a single furnace: When placing glass, it is necessary to reasonably allocate the placement position of each piece of glass according to the size of the electric furnace and the division of heating zones, ensure that the distance between adjacent glass is consistent, avoid placing too much glass in a certain heating zone, leading to excessive load and insufficient heat supply in that zone. At the same time, it is also necessary to avoid glass being placed too scattered, resulting in heat waste and local excessive temperature. When producing glass of different sizes and thicknesses in mixed loading, more attention should be paid to the rationality of the layout, and glass with similar thickness and size should be placed centrally to facilitate precise control of heating parameters. Uniform interval time between each furnace of glass: In the continuous production process, the time interval between the outgoing of glass from the previous furnace and the incoming of glass to the next furnace needs to be kept stable. If the interval time is too long, the temperature in the furnace will fluctuate significantly, and the subsequent glass entering the furnace will take a longer time to reach the set temperature. If the interval time is too short, the heat taken away by the glass from the previous furnace has not been supplemented, and the glass from the next furnace enters the furnace, which will cause a sudden drop in the temperature in the furnace and trigger an overload phenomenon. Therefore, operators need to set a reasonable inter-furnace interval time according to factors such as the heating power of the electric furnace and the heating demand ofglass, and strictly implement it through automatic control systems or manual operations to ensure the stability of the production rhythm. Through the above standard placement arrangement, the uniformity of the furnace load can be effectively guaranteed, providing basic conditions for the uniform heating of glass.   IV. Precisely Controlling the Cooling Process to Ensure Tempering Quality After heating, the glass enters the cooling stage. The cooling rate and cooling uniformity directly determine the tempering effect of the glass. According to the formation principle of temperedglass, the glass in a softened state needs to be cooled as quickly as possible to form a uniform compressive stress layer on the surface. However, the cooling rate is not as fast as possible. It needs to match the thickness, type and other properties of the glass. At the same time, it is necessary to ensure the balanced cooling of the front and back sides of the glass to avoid internal stress caused by uneven cooling leading toglass breakage. The core influencing factors of cooling rate include glass thickness and glass physical properties. Generally speaking, the cooling rate of thin glass can be appropriately increased, while the cooling rate of thick glass needs to be controlled to avoid cracks caused by excessive temperature difference between inside and outside. For example, the thickness of 5mm glass is relatively thin, and the heat conduction rate is relatively fast. The required cooling capacity is more than twice that of 6mm glass. This is because thin glass loses heat quickly during the cooling process and needs stronger cooling capacity to achieve rapid and uniform cooling. However, thickglass loses heat slowly. If the cooling capacity is too strong, it will cause the surface to cool and shrink rapidly, and the internal heat cannot be dissipated in time, forming a huge temperature gradient and internal stress, leading to breakage.   In the selection of cooling medium, the ideal cooling medium for the cooling stage in the tempering process is dry cold air. Dry cold air can avoid the condensation of moisture on the surface of glass, prevent defects such as watermarks and fog spots onglass, and at the same time, the specific heat capacity of cold air is stable, and the cooling effect is uniform and controllable. To ensure the cooling effect, the air volume and wind speed of the cooling system need to be precisely adjusted according to the glass thickness to ensure that the cooling capacity per unit area meets the set standard. In addition, the design of the cooling air grid also needs to be scientific and reasonable. The air outlets of the air grid should be evenly distributed to ensure that the front and back sides of the glass can obtain the same cooling air volume and wind speed, realizing balanced cooling. V. Controlling Glass Movement State to Avoid Surface Defects and Breakage Risks In the entire tempering process, the movement state of glass has a direct impact on product quality. It is required that the glass maintains continuous and stable movement during the production process, and there should be no scratches or marks left by deformation on the glass surface. This movement mainly includes the following two stages: Hot swing movement in the heating furnace: Its core purpose is to enable each part of the glass surface to absorb heat uniformly. Due to the possible slight temperature difference in different areas of the electric furnace, the glass can make different parts of the surface alternately in different heating areas through slow reciprocating swing, thereby making up for the slight unevenness of the temperature field and ensuring the uniform heating of the entire glass. The speed and amplitude of the hot swing movement need to be strictly controlled. Excessively fast speed may cause the glass to collide with the furnace components, resulting in surface scratches. Excessively slow speed cannot achieve the effect of uniform heating. Excessively large amplitude may cause bending deformation of the glass edge, and excessively small amplitude makes the effect of uniform heating not obvious. Cold swing movement in the air cooling section: It is mainly to ensure the uniform cooling of glass, and then make the broken pieces of glass uniform after breaking. During the cooling process, the glass can make each part of the surface evenly contact the cooling air flow through reciprocating swing, avoiding local excessive or slow cooling. Uniform cold swing movement can ensure the uniform distribution of compressive stress on the glass surface, which not only can improve the tempering strength of glass, but also ensure that when the glass breaks due to impact, the broken pieces present uniform small particles, meeting the standard requirements of safety glass. In addition to the control of the movement state, the quality of the original glass also has an important impact on the tempering effect. The original glass should not have defects such as scratches, bubbles, stones and cracks. These defects will become stress concentration points. During the heating and cooling process, the stress at the defect location will increase sharply, eventually causing glass breakage. Therefore, it is necessary to strictly inspect the original glass before production, remove the glass with defects, and ensure the quality of tempered glass products from the source. At the same time, during the handling and placement of glass, protective measures should be taken to avoid scratches or collision damage on the glass surface.   VI. Conclusion In summary, links such as heating temperature selection, furnace temperature control, heating time setting, glass arrangement, cooling process and glass movement control in the glass tempering process are interrelated and mutually influential, jointly determining the product quality of tempered glass. In actual production, operators need to deeply understand the core logic of each process point, accurately set the heating temperature and heating time based on basic parameters such as glass thickness and type, optimize theglass placement arrangement, strictly control the cooling rate and uniformity, standardize the control of glass movement state, and strengthen the inspection of original sheets and equipment maintenance. Only through comprehensive and refined process control can the yield rate and quality stability of tempered glass be effectively improved, meeting the performance requirements of tempered glass in different application scenarios, and promoting the high-quality development of the glass tempering production industry.

The Breakthrough in Fragmentation: How Tempered Glass Reshaped Our Transparent World Prologue: The Civilization's Pursuit from Fragility to Strength In the long river of human civilization, glass has always played a unique role. From ancient Egyptian faience to Roman blown vessels, it fused art with utility. However, the fragility of traditional glass, like an invisible shackle, limited the boundaries of its application. This limitation was not completely broken until the advent of tempered glass. It is not merely an innovation in material but a revolution in safety philosophy—it supports the framework of modern life in an almost invisible way, liberating us from the enduring fear of shattering.   Chapter 1: The Song of Ice and Fire—The Birth of Tempered Glass The birth of tempered glass was not an overnight achievement but a story of exploration spanning centuries. The Source of Inspiration: Prince Rupert's Drops The "Prince Rupert's Drops" circulating in 17th-century European courts were the starting point. Drops formed by molten glass falling into cold water had tails hard enough to withstand hammer blows, yet would instantly explode into powder if the tail was snapped. This marvelous phenomenon was actually a primitive manifestation of surface compressive stress—rapid cooling solidified and contracted the surface, compressing the interior to form a stress layer. However, the science of the time failed to unveil its mystery. The Prelude to Breakthrough: Early Patents and Explorations In the mid-19th century, dawn began to appear. In 1857, the Frenchman Alfred Royer and the German Siemens company obtained similar patents, both attempting to strengthen glass by immersing hot glass into a cold bath for quenching. Although the process was unstable, it pointed the way for the future. Laying the Foundation of an Era: The Establishment of Scientific Quenching The real leap occurred in the early 20th century. With a deeper understanding of the thermodynamic properties of glass, scientists began to systematically control heating and cooling. In 1929, French chemist Louis Gilet achieved a crucial breakthrough: he uniformly heated glass to near its softening point (approximately 620-650°C), then simultaneously blasted high-speed, uniform cold air onto both surfaces. This air quenching process caused the glass surface to solidify rapidly, forming a strong, uniform compressive stress layer, while the interior formed a balancing tensile stress. At this point, the technology for industrially producible physically tempered glass officially took the stage of history.   Chapter 2: Remodeling the Framework—The Scientific Core of Tempering How does an ordinary pane of glass gain new life through the "trial of ice and fire"? The core lies in the ingenious restructuring of its internal stress. Detailed Process Flow: Heating: The glass is precisely heated to a critical temperature in a tempering furnace, where its internal structure becomes loose and fluid. Quenching: The glass is quickly moved into the quenching zone, subjected to intense, uniform blasts of cold air from multiple nozzles. Stress Formation: The surface layer, cooling rapidly, attempts to contract but is "held back" by the still-expanding hot interior. Ultimately, a high compressive stress layer forms on the surface. As the interior cools and contracts, it is "propped up" by the solidified surface, forming tensile stress. This "compressive on the outside, tensile on the inside" stress structure is the physical source of all the extraordinary properties of tempered glass.   Chapter 3: Extraordinary Qualities—The Perfect Union of Safety and Strength The reorganized stress endows tempered glass with a series of revolutionary properties: Intrinsic Safety: When subjected to a strong impact, it does not produce sharp shards but disintegrates into numerous tiny, blunt-angled granules, greatly reducing the risk of cuts. This is the cornerstone of its identity as safety glass. Multiplied Strength: Its surface bending and impact resistance can be 3 to 5 times that of ordinary glass. Exceptional Thermal Stability: It can withstand rapid temperature changes of about 250-300°C, far surpassing ordinary glass. Additionally, it possesses good flexural resistance and vibration resistance.   Chapter 4: Family Evolution—Types and Expanded Applications of Tempered Glass Technological progress has spawned a large family of tempered glasses to meet extreme demands in different scenarios.   Type Core Principle Key Characteristics Typical Applications Physically Tempered Glass Air quenching to form surface compressive stress. High strength, good safety, relatively low cost. The mainstream product with the widest application. Building curtain walls, doors/windows, furniture, appliance panels. Chemically Tempered Glass Ion exchange (e.g., potassium replacing sodium) creates a compressive stress layer on the surface. Extremely high strength, no distortion, suitable for thin and irregularly shaped glass, but high cost and thin stress layer. Smartphone screens, aircraft windows, precision instrument covers. Laminated Glass Two or more layers of glass (often including tempered glass) bonded with an interlayer (e.g., PVB film). Fragments do not fall out upon breakage, maintaining integrity; good intrusion prevention and sound insulation. Automotive windshields, bank display windows, building skylights. Insulating Glass (Double Glazing) Two or more panes sealed with a spacer to form a dry gas-filled cavity. Excellent thermal insulation, soundproofing, anti-condensation properties. Energy-efficient building doors/windows, curtain walls.   Chapter 5: The Transparent Revolution—Reshaping the Face of the Modern World Tempered glass has silently permeated and now supports various dimensions of modern civilization. Architectural Revolution: It liberated architects' imaginations. From early glass curtain walls to today's forests of skyscrapers, combinations of tempered, laminated, and insulating glass have made buildings light, transparent, and energy-efficient, achieving a visual fusion of people and nature. Cornerstone of Transportation Safety: As a core material for car side windows and high-speed train windows, it works together with laminated glass to form a safety barrier in motion, safeguarding billions of journeys. Standard in Daily Life: From heat-resistant oven doors and safe shower enclosures to the sturdy screen covers of smartphones (an evolution of chemical tempering), we live in a transparent world gently enveloped by tempered glass. Chapter 6: Future Horizons—Evolution Knows No Bounds Entering the 21st century, the evolution of tempered glass has accelerated: Pushing Performance Limits: Ultra-thin, curved, high-strength aluminosilicate glass (e.g., "Gorilla Glass") continuously breaks records for strength and toughness. Functional Intelligence: Electrochromic glass, switchable glass, etc., combine tempering with smart materials, transforming glass from a static component into a dynamically controllable interface. Expanding Frontiers: In cutting-edge fields like flexible displays, new energy, deep-sea exploration, and even space architecture, next-generation tempering technologies are dedicated to unlocking new realms of "transparent" possibilities. Epilogue: The Power of Transparency Looking back at the history of tempered glass, it evolved from a chance discovery into a foundational technology defining safety standards. Its true greatness lies in perfectly unifying the ancient contradiction between "transparency" and "strength". Every time we safely walk through a glass door, every time we lean against a panoramic curtain wall to gaze out, every time a screen withstands an impact unscathed, it is a silent tribute to this nearly two-century-long "strengthening" revolution. It has not only reshaped our material world but also profoundly reshaped our perception and trust in safety. In the future, this clear and resilient technology will undoubtedly continue to reflect and guard humanity's progress toward a brighter path in its unique way.